Control system for work vehicle, method, and work vehicle

ABSTRACT

A work vehicle includes a work implement. A control system for the work vehicle includes an operating device and a controller. The operating device outputs an operation signal indicative of an operation by an operator. The controller communicates with the operating device and controls the work implement. The controller determines a first target design topography. The controller generates a command signal to operate a work implement in accordance with the first target design topography. The controller obtains a displacement amount of the work implement with respect to the first target design topography upon receiving the operation signal indicative of the operation of the work implement during work in accordance with the first target design topography. The controller determines a second target design topography based on the displacement amount. The controller generates a command signal to operate the work implement in accordance with the second target design topography.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a U.S. National stage application of International Application No. PCT/JP2019/005833, filed on Feb. 18, 2019. This U.S. National stage application claims priority under 35 U.S.C. § 119(a) to Japanese Patent Application No. 2018-062238, filed in Japan on Mar. 28, 2018, the entire contents of which are hereby incorporated herein by reference.

BACKGROUND Field of the Invention

The present invention relates to a control system for a work vehicle, a method, and a work vehicle.

Background Information

A control for automatically adjusting the position of a work implement such as a blade has been conventionally proposed for work vehicles such as bulldozers or graders and the like. For example, Japanese Patent Publication No. 5247939 describes automatically adjusting a blade by controlling the load so that the load applied to the blade matches a target load during excavating work.

SUMMARY

According to the abovementioned conventional control, the occurrence of shoe slip can be suppressed by raising the blade when the load on the blade becomes excessive. As a result, work can be performed with good efficiency.

However, as illustrated in FIG. 20, in the conventional control, first the blade is controlled so as to follow a design topography 100. Thereafter, when the load on the blade becomes large, the blade is raised due to the load control (see the locus 200 of the blade in FIG. 20). Therefore, when the blade is in a position deep in the design topography 100 with respect to the actual topography 300, the load applied to the blade increases very quickly whereby the blade may be raised very quickly. In this case, because the terrain is formed with large undulations, it may be difficult to carry out excavating work smoothly. Moreover, there is a concern that the excavated terrain may easily become rough and the quality of the finish may decrease.

An object of the present invention is to cause a work vehicle to perform work efficiently and with a good finish quality with automatic control.

A first aspect is a control system for a work vehicle including a work implement, the control system including an operating device and a controller. The operating device outputs an operation signal indicating an operation by an operator. The controller communicates with the operating device and controls the work implement. The controller is programmed so as to execute the following processes. The controller determines a first target design topography. The controller generates a command signal for operating the work implement in accordance with the first target design topography. The controller obtains a displacement amount of the work implement from the first target design topography upon receiving the operation signal which indicates an operation of the work implement by the operator during work in accordance with the first target design topography. The controller determines a second target design topography based on the displacement amount. The controller generates a command signal for operating the work implement in accordance with the second target design topography.

A second aspect is a method executed by the controller in order to control a work vehicle including a work implement, the method including the following processes. A first process includes determining a first target design topography. A second process includes generating a command signal for operating the work implement in accordance with the first target design topography. A third process includes receiving an operation signal which indicates an operation by an operator, from an operating device. A fourth process includes obtaining a displacement amount of the work implement from the first target design topography upon receiving the operation signal which indicates an operation of the work implement by the operator during work in accordance with the first target design topography. A fifth process includes determining a second target design topography based on the displacement amount. A sixth process includes generating a command signal for operating the work implement in accordance with the second target design topography.

A third aspect is a work vehicle, the work vehicle including a work implement, an operating device, and a controller. The operating device outputs an operation signal indicating an operation by an operator. The controller receives the operation signal and controls the work implement. The controller is programmed so as to execute the following processes. The controller determines a first target design topography. The controller generates a command signal for operating the work implement in accordance with the first target design topography. The controller obtains a displacement amount of the work implement from the first target design topography upon receiving the operation signal which indicates an operation of the work implement by the operator during work in accordance with the first target design topography. The controller determines a second target design topography based on the displacement amount. The controller generates a command signal for operating the work implement in accordance with the second target design topography.

According to the present invention, a work vehicle can be made to perform work efficiently and with a good finish quality with automatic control.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 is a side view of a work vehicle according to an embodiment.

FIG. 2 is a block diagram of a configuration of a drive system and a control system of the work vehicle.

FIG. 3 is a schematic view of a configuration of the work vehicle.

FIG. 4 is a flow chart of an automatic control process of the work vehicle.

FIG. 5 illustrates examples of a final design topography, an actual topography, and a target design topography.

FIG. 6 is a flow chart of a process for determining the target design topography.

FIG. 7 illustrates a process for determining the target design topography.

FIG. 8 illustrates a process for determining the target design topography.

FIG. 9 illustrates a process for determining the target design topography.

FIG. 10 illustrates a process for determining the target design topography.

FIG. 11 illustrates a process for determining the target design topography.

FIG. 12 illustrates a process for determining the target design topography.

FIG. 13 is a flow chart of a process when a manual operation is introduced.

FIG. 14 illustrates a process when a manual operation is introduced.

FIG. 15 illustrates a process when a manual operation is introduced.

FIG. 16 illustrates a process when a manual operation is introduced.

FIG. 17 is a block diagram of a configuration of a drive system and a control system of the work vehicle according to a first modified example.

FIG. 18 is a block diagram of a configuration of a drive system and a control system of the work vehicle according to a second modified example.

FIG. 19 illustrates a process when a manual operation is introduced according to another embodiment.

FIG. 20 illustrates excavation work according to the prior art.

DETAILED DESCRIPTION OF EMBODIMENT(S)

A work vehicle according to an embodiment is discussed hereinbelow with reference to the drawings. FIG. 1 is a side view of a work vehicle 1 according to an embodiment. The work vehicle 1 according to the present embodiment is a bulldozer. The work vehicle 1 includes a vehicle body 11, a travel device 12, and a work implement 13.

The vehicle body 11 has an operating cabin 14 and an engine compartment 15. An operator's seat that is not illustrated is disposed inside the operating cabin 14. The engine compartment 15 is disposed in front of the operating cabin 14. The travel device 12 is attached to a bottom part of the vehicle body 11. The travel device 12 has a pair of left and right crawler belts 16. Only the crawler belt 16 on the left side is illustrated in FIG. 1. The work vehicle 1 travels due to the rotation of the crawler belts 16.

The work implement 13 is attached to the vehicle body 11. The work implement 13 has a lift frame 17, a blade 18, and a lift cylinder 19. The lift frame 17 is attached to the vehicle body 11 in a manner that allows movement up and down centered on an axis X that extends in the vehicle width direction. The lift frame 17 supports the blade 18.

The blade 18 is disposed in front of the vehicle body 11. The blade 18 moves up and down accompanying the up and down motion of the lift frame 17. The lift frame 17 may be attached to the travel device 12. The lift cylinder 19 is coupled to the vehicle body 11 and the lift frame 17. Due to the extension and contraction of the lift cylinder 19, the lift frame 17 rotates up and down centered on the axis X.

FIG. 2 is a block diagram of a configuration of a drive system 2 and a control system 3 of the work vehicle 1. As illustrated in FIG. 2, the drive system 2 includes an engine 22, a hydraulic pump 23, and a power transmission device 24.

The hydraulic pump 23 is driven by the engine 22 to discharge hydraulic fluid. The hydraulic fluid discharged from the hydraulic pump 23 is supplied to the lift cylinder 19. While only one hydraulic pump 23 is illustrated in FIG. 2, a plurality of hydraulic pumps may be provided.

The power transmission device 24 transmits driving power from the engine 22 to the travel device 12. The power transmission device 24 may be a hydrostatic transmission (HST), for example. Alternatively, the power transmission device 24, for example, may be a transmission including a torque converter or a plurality of speed change gears.

The control system 3 includes an operating device 25 a, an input device 25 b, a controller 26, a storage device 28, and a control valve 27. The operating device 25 a and the input device 25 b are disposed in the operating cabin 14. The operating device 25 a is a device for operating the work implement 13 and the travel device 12. The operating device 25 a is disposed in the operating cabin 14. The operating device 25 a receives operations from an operator for driving the work implement 13 and the travel device 12, and outputs operation signals in accordance with the operations. The operating device 25 a includes, for example, an operating lever, a pedal, and a switch and the like.

The input device 25 b is a device for performing belowmentioned automatic control settings of the work vehicle 1. The input device 25 b receives an operation by an operator and outputs an operation signal corresponding to the operation. The operation signals of the input device 25 b are output to the controller 26. The input device 25 b is, for example, a touch screen display. However, the input device 25 b is not limited to a touch screen and may include hardware keys.

The controller 26 is programmed so as to control the work vehicle 1 based on obtained data. The controller 26 includes, for example, a processing device (processor) such as a CPU. The controller 26 obtains operation signals from the operating device 25 a and the input device 25 b. The controller 26 is not limited to one component and may be divided into a plurality of controllers. The controller 26 controls the travel device 12 or the power transmission device 24 thereby causing the work vehicle 1 to travel. The controller 26 controls the control valve 27 thereby causing the blade 18 to move up and down.

The control valve 27 is a proportional control valve and is controlled with command signals from the controller 26. The control valve 27 is disposed between the hydraulic pump 23 and hydraulic actuators such as the lift cylinder 19. The control valve 27 controls the flow rate of the hydraulic fluid supplied from the hydraulic pump 23 to the lift cylinder 19. The controller 26 generates a command signal to the control valve 27 so that the blade 18 moves. As a result, the lift cylinder 19 is controlled. The control valve 27 may also be a pressure proportional control valve. Alternatively, the control valve 27 may be an electromagnetic proportional control valve.

The control system 3 includes a work implement sensor 29. The work implement sensor 29 detects the position of the work implement 13 and outputs a work implement position signal which indicates the position of the work implement 13. The work implement sensor 29 may be a displacement sensor that detects displacement of the work implement 13. Specifically, the work implement sensor 29 detects the stroke length (referred to below as “lift cylinder length L”) of the lift cylinder 19. As illustrated in FIG. 3, the controller 26 calculates a lift angle θlift of the blade 18 based on the lift cylinder length L. The work implement sensor 29 may be a rotation sensor that directly detects the rotation angle of the work implement 13.

FIG. 3 is a schematic view of a configuration of the work vehicle 1. The reference position of the work implement 13 is depicted as a chain double-dashed line in FIG. 3. The reference position of the work implement 13 is the position of the blade 18 while the blade tip of the blade 18 is in contact with the ground surface on a horizontal ground surface. The lift angle θlift is the angle from the reference position of the work implement 13.

As illustrated in FIG. 2, the control system 3 includes a positional sensor 31. The positional sensor 31 measures the position of the work vehicle 1. The positional sensor 31 includes a global navigation satellite system (GNSS) receiver 32 and an IMU 33. The GNSS receiver 32 is, for example, a receiving apparatus for a global positioning system (GPS). For example, an antenna of the GNSS receiver 32 is disposed on the operating cabin 14. The GNSS receiver 32 receives a positioning signal from a satellite, computes the position of the antenna from the positioning signal, and generates vehicle body position data. The controller 26 obtains the vehicle body position data from the GNSS receiver 32. The controller 26 derives the traveling direction and the vehicle speed of the work vehicle 1 from the vehicle body position data.

The vehicle body position data may not be data of the antenna position. The vehicle body position data may be data that indicates a position of an arbitrary position having a fixed positional relationship with an antenna inside the work vehicle 1 or in the surroundings of the work vehicle 1.

The IMU 33 is an inertial measurement device. The IMU 33 obtains vehicle body inclination angle data. The vehicle body inclination angle data includes the angle (pitch angle) relative to horizontal in the vehicle front-back direction and the angle (roll angle) relative to horizontal in the vehicle lateral direction. The controller 26 obtains the vehicle body inclination angle data from the IMU 33.

The controller 26 computes a blade tip position Pb from the lift cylinder length L, the vehicle body position data, and the vehicle body inclination angle data. As illustrated in FIG. 3, the controller 26 calculates global coordinates of the GNSS receiver 32 based on the vehicle body position data. The controller 26 calculates the lift angle θlift based on the lift cylinder length L. The controller 26 calculates local coordinates of the blade tip position Pb with respect to the GNSS receiver 32 based on the lift angle θlift and vehicle body dimension data. The vehicle body dimension data is stored in the storage device 28 and indicates the position of the work implement 13 with respect to the GNSS receiver 32. The controller 26 calculates the global coordinates of the blade tip position Pb based on the global coordinates of the GNSS receiver 32, the local coordinates of the blade tip position Pb, and the vehicle body inclination angle data. The controller 26 obtains the global coordinates of the blade tip position Pb as blade tip position data.

The storage device 28 includes, for example, a memory and an auxiliary storage device. The storage device 28 may be a RAM or a ROM, for example. The storage device 28 may be a semiconductor memory or a hard disk and the like. The storage device 28 is an example of a non-transitory computer-readable recording medium. The storage device 28 records computer commands for controlling the work vehicle 1 and that are executable by the processor.

The storage device 28 stores design topography data and work site topography data. The design topography data indicates the final design topography. The final design topography is the final target shape of the surface of a work site. The work site topography data is, for example, a civil engineering diagram map in a three-dimensional data format. The work site topography data indicates the topography of a wide area of the work site. The work site topography data is, for example, an actual topographical survey map in a three-dimensional data format. The work site topography data can be derived, for example, from an aerial laser survey.

The controller 26 obtains actual topography data. The actual topography data indicates the actual topography of the work site. The actual topography of the work site is the topography of an area in the traveling direction of the work vehicle 1. The actual topography data is obtained by computations by the controller 26 from the work site topography data, the position of the work vehicle 1 obtained by the abovementioned positional sensor 31, and from the traveling direction. The actual topography data may be obtained by performing distance surveying on the actual topography with an on-board laser imaging detection and ranging device (LIDAR).

The controller 26 automatically controls the work implement 13 based on the actual topography data, the design topography data, and the blade tip position data. The automatic control of the work implement 13 may be a semi-automatic control that is performed in accompaniment with manual operations by the operator. Alternatively, the automatic control of the work implement 13 may be a fully automatic control that is performed without manual operations by an operator. The traveling of the work vehicle 1 may be controlled automatically by the controller 26. For example, the travel control of the work vehicle 1 may be a fully automatic control that is performed without manual operations by an operator. Alternatively, the travel control may be a semi-automatic control that is performed in accompaniment with manual operations by an operator. Alternatively, the travel of the work vehicle 1 may be performed with manual operations by the operator.

Automatic control of the work vehicle 1 during excavation and executed by the controller 26 will be explained below. The controller 26 starts the automatic control when a predetermined starting condition is met. The predetermined starting condition may be, for example, that an operation signal which indicates a lowering operation of the work implement 13 is received from the operating device 25 a. Alternatively, the predetermined starting condition may be that an operation signal indicating an automatic control starting command is received by the controller 26 from the input device 25b.

FIG. 4 is a flow chart of automatic control processes of the work vehicle 1. As illustrated in FIG. 4, the controller 26 obtains the current position data in step S101. The controller 26 obtains the current blade tip position Pb of the work implement 13 as indicated above.

In step S102, the controller 31 obtains the design topography data. As illustrated in FIG. 5, the design topography data includes a height Zdesign of a final design topography 60 at a plurality of reference points Pn (n=0, 1, 2, 3, . . . , A) in the traveling direction of the work vehicle 1. The plurality of reference points Pn indicate a plurality of spots at predetermined intervals in the traveling direction of the work vehicle 1. The plurality of reference points Pn are on the travel path of the blade 18. In FIG. 5, while the final design topography 60 has a shape that is flat and parallel to the horizontal direction, the shape of the final design topography 60 may be different.

In step S103, the controller 26 obtains the actual topography data. The controller 26 obtains the actual topography data by computations of the work site topography data obtained from the storage device 28 and the vehicle body position data and the traveling direction data obtained by the positional sensor 31.

The actual topography data is information which indicates the topography located in the traveling direction of the work vehicle 1. FIG. 5 illustrates a cross-section of actual topography 50. In FIG. 5, the vertical axis indicates the height of the topography and the horizontal axis indicates the distance from the current position in the traveling direction of the work vehicle 1.

Specifically, the actual topography data includes a height Zn of the actual topography 50 at each of the plurality of reference points Pn from the current position to a predetermined topography recognition distance dA in the traveling direction of the work vehicle 1. In the present embodiment, the current position may be a position defined based on the current blade tip position Pb of the work vehicle 1. However, the current position may also be defined based on the current position of another portion of the work vehicle 1. The plurality of reference points are aligned with a predetermined interval, for example 1 m, between each point.

In step S104, the controller 26 determines the target design topography data. The target design topography data represents a target design topography 70 indicated by the dashed line in FIG. 5. The target design topography 70 represents a desired locus of the blade tip of the blade 18 during the work. The target design topography 70 is a target profile of the topography that is the work object and represents the desired shape as a result of the excavating work. As illustrated in FIG. 5, the controller 26 determines at least a portion of the target design topography 70 located below the actual topography 50.

The controller 26 determines the target design topography 70 so as not to go below the final design topography 60. Therefore, the controller 26 determines the target design topography 70 located above the final design topography 60 and below the actual topography 50 during the excavating work.

In step S105, the controller 26 controls the work implement 13 in accordance with the target design topography 70. The controller 26 generates command signals for the work implement 13 so as to move the blade tip position of the blade 18 in accordance with the target design topography 70. The generated command signal is inputted to the control valve 27. Consequently, the blade tip position PB of the blade 18 moves toward the target design topography 70.

In step S106, the controller 26 updates the work site topography data. The controller 26 updates the work site topography data with the position data that indicates the most recent locus of the blade tip position Pb. The update of the work site topography data may be performed at any time. Alternatively, the controller 26 may calculate the location of the bottom surface of the crawler belts 16 from the vehicle body position data and the vehicle body dimension data, and may update the work site topography data with the position data that indicates the locus of the bottom surface of the crawler belts 16. In this case, the updating of the work site topography data can be performed promptly.

Alternatively, the work site topography data may be generated from survey data measured by a survey device outside of the work vehicle 1. For example, aerial laser surveying may be used as the external measurement device. Alternatively, the actual topography 50 may be imaged by a camera and the work site topography data may be generated from image data captured by the camera. For example, aerial photography surveying performed with an unmanned aerial vehicle (UAV) may be used. When using the external surveying device or a camera, the updating of the work site topography data may be performed at predetermined periods or at any time.

By repeating the above processes, the excavating is performed so that the actual topography 50 approaches the final design topography 60.

The processing for determining the target design topography 70 is explained in detail below. FIG. 6 is a flow chart of a process for determining the target design topography 70. As illustrated in FIG. 6, in step S201, the controller 26 determines a starting point S0. As illustrated in FIG. 7, the controller 26 determines, as the starting point S, a position that is a predetermined distance L1 in front of the blade tip position Pb at the point in time that the automatic control starts. The predetermined distance L1 is saved in the storage device 28. The input device 25 b may be used to allow setting of the predetermined distance L1.

In step S202, the controller 26 determines a plurality of division points An (n=1, 2, . . . ) based on the actual topography data. As illustrated in FIG. 7, the controller 26 demarcates the actual topography 50 into a plurality of divisions according to the division points An. The division points An are spots positioned away from each other by a predetermined interval L2 on the actual topography 50. The predetermined interval L2 is, for example, 3 m. However, the predetermined interval L2 may be less than 3 m or greater than 3 m. The predetermined interval L2 is saved in the storage device 28. The input device 25 b may be used to allow setting of the predetermined interval L2. The controller 26 determines, as the division points An, a plurality of spots at each predetermined interval L2 in the traveling direction of the work vehicle 1 from the starting point S0.

In step S203, the controller 26 smooths the actual topography data. The controller 26 smooths the actual topography data by linear interpolation. Specifically, as illustrated in FIG. 8, the controller 26 smooths the actual topography data by replacing the actual topography 50 with straight lines that link each of the division points An.

In step S204, the controller 26 determines a target depth L3. The controller 26 determines the target depth L3 in accordance with a control mode set with the input device 25 b. For example, the operator is able to select any of a first mode, a second mode, and a third mode with the input device 25 b. The first mode is a control mode with the greatest load and the third mode is a control mode with the smallest load. The second mode is a control mode with a load between the first mode and the third mode.

The target depths L3 corresponding to each mode are saved in the storage device 28. The controller 26 selects, as the target depth L3, a first target depth of the first mode, a second target depth of the second mode, or a third target depth of the third mode. The first target depth is greater than the second target depth. The second target depth is greater than the third target depth. The input device 25 b may be used to allow optional setting of the target depth L3.

In step S205, the controller 26 determines a plurality of reference points. As illustrated in FIG. 9, the controller 26 determines, as respective reference points B1 and B2, spots displaced downward by the target depth L3 from the first preceding division point A1 and from the second preceding division point A2.

In step S206, the controller 26 determines a plurality of reference topographies. As illustrated in FIG. 9, the controller 26 determines a first reference topography C1 and a second reference topography C2. The first reference topography C1 is represented by a straight line that links the starting point S0 and the first preceding reference point B1. The second reference topography C2 is represented by a straight line that links the starting point S0 and the second preceding reference point B2.

In step S207, the controller 26 determines the target design topography 70. The controller 26 determines the target design topography 70 for each division demarcated by the plurality of division points An. As illustrated in FIG. 10, the controller 26 determines a first target design topography 70_1 that passes between the first reference topography C1 and the second reference topography C2. The first target design topography 70_1 is the target design topography 70 in the division (referred to below as “first division”) between the starting point S0 and the first preceding division point A1.

Specifically, the controller 26 calculates the average angle of the first reference topography C1 and the second reference topography C2. The average angle is the average value between the angle of the first reference topography C1 with respect to the horizontal direction and the angle of the second reference topography C2 with respect to the horizontal direction The controller 26 determines, as the first target design topography 70_1, a straight line that is inclined by the average angle with respect to the horizontal direction.

When the first target design topography 70_1 is determined as indicated above, the controller 26 controls the work implement 13 in accordance with the first target design topography 70_1 in accordance with the abovementioned process of step S105 as illustrated in FIG. 11.

In step S208, the controller 26 determines the next starting point S1. The next starting point S1 is the starting point of the next target design topography 70, namely a second target design topography 70_2. The second target design topography 70_2 is the target design topography 70 in the division (referred to below as the “second division”) between the next starting point S1 and the first preceding division point A2. As illustrated in FIG. 12, the next starting point S1 is the end position of the first target design topography 70_1 and is positioned directly below the division point A1.

Upon determining the next starting point S1, the controller 26 determines the second target design topography 70_2 by repeating the processes from step S205 to step S207. The controller 26 determines the second target design topography 70_2 while working in accordance with the first target design topography 70_1.

Specifically, as illustrated in FIG. 12, the controller 26 determines, as the next first reference topography C1, a straight line that links the next starting point S1 and the first preceding reference point B2. The controller 26 also determines, as the next second reference topography C2, a straight line that links the next starting point S1 and the second preceding reference point B3. The controller 26 determines the second target design topography 70_2 from the average angle of the first reference topography C1 and the second reference topography C2.

When the work vehicle 1 reaches the next starting point S1, the controller 26 controls the work implement 13 in accordance with the second target design topography 70_2 in accordance with the abovementioned process of step S105. The controller 26 then continues the excavation of the actual topography 50 by repeating the above processes.

When a predetermined completion condition is satisfied, the controller 26 finishes the abovementioned processes for determining the target design topography 70. The predetermined completion condition is, for example, that the amount of material held by the work implement 13 has reached a predetermined upper limit. When the predetermined completion condition is satisfied, the controller 26 controls the work implement 13 so as to follow the actual topography 50. Consequently, the excavated material can be transported smoothly.

The process when a manual operation of the work implement 13 is introduced by the operator during the abovementioned automatic control is explained next. FIG. 13 is a flow chart of a process when a manual operation is introduced. In the following explanation as illustrated in FIG. 14, a manual operation of the work implement 13 is introduced by the operator during the work in accordance with the first target design topography 70_1.

In step S301, the controller 26 determines that a manual operation has been performed. The controller 26 determines that a manual operation has been performed when an operation signal which indicates an operation for causing the work implement 13 to move up or down is received from the operating device 25 a. The process advances to S302 when the manual operation is performed.

In step S302, the controller 26 obtains the displacement amount of the work implement 13. Specifically, as illustrated in FIG. 14, the controller 26 calculates a displacement amount L4 in the vertical direction of the blade tip position Pb with respect to the first target design topography 70_1.

In step S303, the controller 26 corrects the target design topography 70 during the current work. That is, as illustrated in FIG. 15, the controller 26 corrects the first target design topography 70_1 so as to match the modified height of the blade tip position Pb. In addition, the controller 26 controls the work implement 13 in accordance with the corrected first target design topography 70_1.

The controller 26 raises the first target design topography 70_1 to match the height of the blade tip position Pb when a raising operation of the work implement 13 is performed. The controller 26 lowers the first target design topography 70_1 to match the height of the blade tip position Pb when a lowering operation of the work implement 13 is performed.

In step S304, the controller 26 corrects the target depth L3 based on the displacement amount L4. When a raising operation of the work implement 13 is performed, the controller 26 reduces the target depth L3 by the displacement amount L4. When a lowering operation of the work implement 13 is performed, the controller 26 increases the target depth L3 by the displacement amount L4.

In step S305, the controller 26 determines the target design topography 70 for the next division based on a corrected target depth L3′. That is, as illustrated in FIG. 16, the controller 26 determines the second target design topography 70_2 based on the corrected target depth L3′. The second target design topography 70_2 is determined in accordance with the abovementioned processes from step S205 to step S207.

Specifically, the controller 26 determines the next starting point S1 from the corrected first target design topography 70_1. The controller 26 determines respective reference points B2 and B3 by displacing the division points A2 and A3 in the vertical direction by the corrected target depth L3′. The controller 26 determines, as the next first reference topography C1, a straight line that links the next starting point S1 and the first preceding reference point B2. The controller 26 also determines, as the next second reference topography C2, a straight line that links the next starting point S1 and the second preceding reference point B3. The controller 26 determines the second target design topography 70_2 from the average angle pf the first reference topography C1 and the second reference topography C2.

When the work vehicle 1 reaches the next starting point S1, the controller 26 controls the work implement 13 in accordance with the second target design topography 70_2 in accordance with the abovementioned process of step S105. The controller 26 then continues the excavation of the actual topography 50 by repeating the above processes.

In the above examples, the first target design topography 70_1 is the target design topography 70 of the first division where the automatic control is started. However, the first target design topography 70_1 may be the target design topography of another division. That is, the first division signifies the division where work is being performed when the manual introduction occurs and is not limited to the target design topography 70 of the first division where the automatic control is started.

In the control system 3 of the work vehicle 1 according to the present embodiment explained above, the controller 26 operates the work implement 13 in accordance with the target design topography 70. As a result, when the final design topography 60 is still in a deep position, excavating by the work implement 13 is performed in accordance with the target design topography 70 that is positioned above the final design topography 60. As a result, a situation in which the load on the work implement 13 becomes excessive is suppressed. In addition, the sudden raising or lowering of the work implement 13 is suppressed. Accordingly, the work vehicle 1 can be made to perform work efficiently and with a good finish quality.

When a manual operation of the work implement 13 is introduced by the operator during the automatic control, the controller 26 corrects the first target design topography 70_1 in response to the displacement amount L4 of the work implement 13. The controller 26 also corrects the target depth L3 in response to the displacement amount L4 of the work implement 13 and determines the second target design topography 70_2 based on the corrected target depth L3′. As a result, the intention of the operator can be reflected in the automatic control.

Although an embodiment of the present invention has been described so far, the present invention is not limited to the above embodiments and various modifications may be made within the scope of the invention.

The work vehicle 1 is not limited to a bulldozer, and may be another type of work vehicle such as a wheel loader, a motor grader, a hydraulic excavator, or the like.

The work vehicle 1 may be a vehicle that can be remotely operated. In this case, a portion of the control system 3 may be disposed outside of the work vehicle 1. For example, the controller 26 may be disposed outside the work vehicle 1. The controller may be disposed inside a control center spaced away from the work site. In this case, the work vehicle 1 may not be provided with the operating cabin 14.

The work vehicle 1 may be driven by an electric motor. In this case, the power source may be disposed outside of the work vehicle 1. The internal combustion engine or the engine compartment may not be provided in the work vehicle 1 in which the power source is supplied from the outside.

The controller 26 may have a plurality of controllers 26 separate from each other. For example, as illustrated in FIG. 17, the controller 26 may include a remote controller 261 disposed outside of the work vehicle 1 and an on-board controller 262 mounted in the work vehicle 1. The remote controller 261 and the on-board controller 262 may be able to communicate wirelessly via communication devices 38 and 39. A portion of the abovementioned functions of the controller 26 may be executed by the remote controller 261, and the remaining functions may be executed by the on-board controller 262. For example, the processing for determining the target design topography 70 may be performed by the remote controller 261, and the process for outputting the command signals to the work implement 13 may be performed by the on-board controller 262.

The operating device 25 a and the input device 25 b may also be disposed outside of the work vehicle 1. In this case, the operating cabin may be omitted from the work vehicle 1. Alternatively, the operating device 25 a and the input device 25 b may be omitted from the work vehicle 1.

The actual topography 50 may be obtained with another device and is not limited to being obtained with the abovementioned positional sensor 31. For example, as illustrated in FIG. 18, the actual topography 50 may be obtained with an interface device 37 that receives data from an external device. The interface device 37 may wirelessly receive the actual topography data measured by an external measurement device 41. Alternatively, the interface device 37 may be a recording medium reading device and may receive the actual topography data measured by the external measurement device 41 via a recording medium.

The method for setting the target design topography 70 is not limited to the method of the above embodiment and may be changed. For example, the target design topography 70 is determined based on two preceding reference points from the starting point in the above embodiment. However, the target design topography 70 may be determined based on three or more preceding reference points from the starting point. The controller 26 may determine the first target design topography 70_1 based on another parameter without being limited to the target depth. For example, the controller 26 may determine the first target design topography 70_1 based on the load on the work implement 13, a target angle, a target position, or another parameter. Alternatively, the first target design topography 70_1 may be determined ahead of time.

The controller 26 determines the target design topography 70 based on the average angle between the first reference topography C1 and the second reference topography C2 in the above embodiment. However, the determination is not limited to the average angle and the controller 26 may determine the target design topography 70 by implementing a process such as weighting the angle of the first reference topography C1 and the angle of the second reference topography C2.

The controller 26 determines the second target design topography 70_2 during the work on the first target design topography 70_1 and before reaching the next starting position S1 in the above embodiment. However, the controller 26 may determine the second target design topography 70_2 upon reaching the next starting point S1.

The controller 26 may determine the target design topography 70 above the actual topography 50. For example, as illustrated in FIG. 19, when the operator raises the blade tip position Pb to a position above the actual topography 50, the controller 26 may raise the first target design topography 70_1 to a position above the actual topography 50 to match the height of the blade tip position Pb. The controller 26 may determine the second target design topography 70_2 so as to be positioned above the actual topography 50. Consequently, for example, the material held by the work implement 13 can be leveled on the actual topography 50.

According to the present invention, a work vehicle can be made to perform work efficiently and with a good finish quality with automatic control. 

1. A control system for a work vehicle including a work implement, the control system comprising: an operating device that outputs an operation signal indicative of an operation by an operator; and a controller that communicates with the operating device and controls the work implement, the controller being configured to determine a first target design topography, generate a command signal to operate the work implement in accordance with the first target design topography, obtain a displacement amount of the work implement with respect to the first target design topography upon receiving the operation signal indicative of the operation of the work implement during work in accordance with the first target design topography, determine a second target design topography based on the displacement amount, and generate a command signal to operate the work implement in accordance with the second target design topography.
 2. The control system for a work vehicle according to claim 1, wherein the controller is further configured to determine a target depth, and determine the first target design topography based on the target depth.
 3. The control system for a work vehicle according to claim 2, wherein the controller is further configured to correct the target depth based on the displacement amount, and determine the second target design topography based on the corrected target depth.
 4. The control system for a work vehicle according to claim 1, wherein the controller is further configured to obtain actual topography data indicative of an actual topography of a work sit; demarcate the actual topography into a plurality of divisions including at least a first division and a second division, determine the first target design topography for the first division, and determine the second target design topography for the second division.
 5. The control system for a work vehicle according to claim 1, wherein the controller is further configured to, upon receiving the operation signal indicative of the operation of the work implement during work in accordance with the first target design topography, correct the first target design topography by displacing the first target design topography by the displacement amount in a vertical direction.
 6. The control system for a work vehicle according to claim 2, wherein the controller is further configured to obtain actual topography data indicative of an actual topography of a work site, obtain, based on the actual topography data, positions of a plurality of division points positioned on the actual topography, determine a plurality of reference points by displacing the plurality of division points in a vertical direction by the target depth, and determine the first target design topography based on the plurality of reference points.
 7. The control system for a work vehicle according to claim 6, wherein the controller is further configured to correct the target depth based on the displacement amount, and upon receiving the operation signal indicative of the operation of the work implement during work in accordance with the first target design topography, determine the second target design topography from the plurality of reference points by displacing the plurality of division points in the vertical direction by the corrected target depth.
 8. A method executed by a controller for controlling a work vehicle including a work implement, the method comprising: determining a first target design topography; generating a command signal to operate the work implement in accordance with the first target design topography; receiving an operation signal indicative of an operation by an operator from an operating device; obtaining a displacement amount of the work implement with respect to the first target design topography upon receiving the operation signal indicative of the operation of the work implement during work in accordance with the first target design topography; determining a second target design topography based on the displacement amount; and generating a command signal to operate the work implement in accordance with the second target design topography.
 9. The method according to claim 8, further comprising: determining a target depth, the first target design topography being determined based on the target depth.
 10. The method according to claim 9, further comprising: correcting the target depth based on the displacement amount, the second target design topography being determined based on the corrected target depth.
 11. The method according to claim 8, further comprising: obtaining actual topography data indicative of an actual topography of a work site; and demarcating the actual topography into a plurality of divisions including at least a first division and a second division, the first target design topography being determined for the first division, and the second target design topography being determined for the second division.
 12. The method according to claim 8, further comprising: upon receiving the operation signal indicative of the operation of the work implement during work in accordance with the first target design topography, correcting the first target design topography by displacing the first target design topography by the displacement amount in a vertical direction.
 13. The method according to claim 9 further comprising: obtaining actual topography data indicative of an actual topography of a work site; and obtaining, based on the actual topography data, positions of a plurality of division points positioned on the actual topography, the determining of the first target design topography including determining a plurality of reference points by displacing the plurality of division points in a vertical direction by the target depth, and determining the first target design topography based on the plurality of reference points.
 14. The method according to claim 13, further comprising: correcting the target depth based on the displacement amount, the determining of the second target design topography including, upon receiving the operation signal indicative of the operation of the work implement during work in accordance with the first target design topography, determining the second target design topography from the plurality of reference points by displacing the plurality of division points in the vertical direction by the corrected target depth.
 15. A work vehicle comprising: a work implement; an operating device that outputs an operation signal indicative of an operation by an operator, and a controller that communicates with the operating device and controls the work implement, the controller being configured to determine a first target design topography, generate a command signal to operate the work implement in accordance with the first target design topography, obtain a displacement amount of the work implement with respect to the first target design topography upon receiving the operation signal indicative of the operation of the work implement during work in accordance with the first target design topography, determine a second target design topography based on the displacement amount, and generate a command signal to operate the work implement in accordance with the second target design topography.
 16. The work vehicle according to claim 15, wherein the controller is further configured to determine a target depth, and determine the first target design topography based on the target depth.
 17. The work vehicle according to claim 16, wherein the controller is further configured to correct the target depth based on the displacement amount, and determine the second target design topography based on the corrected target depth.
 18. The work vehicle according to claim 15, wherein the controller is further configured to obtain actual topography data indicative of an actual topography of a work sit; demarcate the actual topography into a plurality of division including at least a first division and a second division, determine the first target design topography for the first division, and determine the second target design topography for the second division.
 19. The work vehicle according to claim 15, wherein the controller is further configured to, upon receiving the operation signal indicative of the operation of the work implement during work in accordance with the first target design topography, correct the first target design topography by displacing the first target design topography by the displacement amount in a vertical direction.
 20. The work vehicle according to claim 16, wherein the controller is further configured to obtain actual topography data indicative of an actual topography of a work sit; obtain, based on the actual topography data, positions of a plurality of division points positioned on the actual topography, determine a plurality of reference points by displacing the plurality of division points in a vertical direction by the target depth, and determine the first target design topography based on the plurality of reference points.
 21. The work vehicle according to claim 20, wherein the controller is further configured to correct the target depth based on the displacement amount, and upon receiving the operation signal indicative of the operation of the work implement during work in accordance with the first target design topography, determine the second target design topography from the plurality of reference points by displacing the plurality of division points in the vertical direction by the corrected target depth. 